Publications of Michael Ritter
All genres
Journal Article (12)
1.
Journal Article
Shaikhutdinov, S.K., M. Ritter and W. Weiss: Hexagonal hetero-layer(s) on a square lattice: a combined STM and LEED study of FeO(111) on Pt(100). Physical Review B 62 (11), 7535–7541 (2000).
2.
Journal Article
Joseph, Y., C. Kuhrs, W. Ranke, M. Ritter and W. Weiss: Adsorption of water on FeO(111) and Fe3O4(111): identification of active sites for dissociation. Chemical Physics Letters 314 (3-4), 195–202 (1999).
3.
Journal Article
Shaikhutdinov, S.K., M. Ritter, X.G. Wang, H. Over and W. Weiss: Defect structures on epitaxial Fe3O4(111) films. Physical Review B 60 (15), 11062–11069 (1999).
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Journal Article
Ritter, M. and W. Weiss: Fe3O4(111) surface structure determined by LEED crystallography. Surface Science 432 (1-2), 81–94 (1999).
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Journal Article
Cai, Y.Q., M. Ritter, W. Weiss and A.M. Bradshaw: Valence-band structure of epitaxially grown Fe3O4(111) films. Physical Review B 58 (8), 5043–5051 (1998).
9.
Journal Article
Ritter, M., W. Ranke and W. Weiss: Growth and structure of ultrathin FeO films on Pt(111) studied by STM and LEED. Physical Review B 57 (12), 7240–7251 (1998).
10.
Journal Article
Wang, X.-G., W. Weiss, S.K. Shaikhutdinov, M. Ritter, M. Petersen, F. Wagner, R. Schlögl and M. Scheffler: The Hematite (α-Fe2O3) (0001) Surface: Evidence for Domains of Distinct Chemistry. Physical Review Letters 81 (5), 1038–1041 (1998).
11.
Journal Article
Weiss, W., M. Ritter, D. Zscherpel, M. Swoboda and R. Schlögl: Multicomponent surface analysis system combined with high pressure reaction cells for studying metal oxide model catalysts. Journal of Vacuum Science and Technology A 16 (1), 21–29 (1998).
12.
Journal Article
Ritter, M., H. Over and W. Weiss: Structure of epitaxial iron oxide films grown on Pt(100) determined by low energy electron diffraction. Surface Science 371 (2-3), 245–254 (1997).
Talk (1)
Poster (1)
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Poster
Thesis - PhD (1)
15.
Thesis - PhD
Ritter, M.: On the atomic and mesoscopic surface structure of single-crystalline iron-oxide films. Technische Universität Berlin